Metal‐Folded Single‐Chain Nanoparticle: Nanoclusters and Self‐Assembled Reduction‐Responsive Sub‐5‐nm Discrete Subdomains

Cui, Zhigang; Gao, Pan; Ding, Yi; Zhu, Xuechao; Lu, Xinhua; Cai, Yuanli

doi:10.1002/marc.201700269

Cited by 7 publications

(5 citation statements)

References 43 publications

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“…107 In addition, the groups of Rotello and Weck used π-stacking interactions between homo-and heteroaromatic pendants for the reversible folding of copolymers, while O'Reilly and coworkers [108][109][110][111] used ionic interactions. Recently, Artar, 112,113 Cai, [114][115][116] Pomposo, [117][118][119] Lemcoff, [120][121][122] Barner-Kowollik, [123][124][125] Zimmerman, 126 and others have been using a wide variety of metal-ligand complexations to collapse polymer chains. [127][128][129][130][131][132][133] Folding using directional supramolecular motifs in organic media…”

Section: Folding Polymers Via Hydrogen-bond-driven Dimerizationmentioning

confidence: 99%

Supramolecular Single-Chain Polymeric Nanoparticles

Huurne¹,

Palmans

2019

CCS Chem

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Nature has unparalleled control over the conformation and dynamics of its folded macromolecular structures. Nature’s ability to arrange amino acids into a precise spatial organization by way of folding allows proteins to fulfill specific functions in an extremely efficient manner. Chemists and materials scientists have used the delicate structure–function relationships observed in proteins to elucidate nature’s design principles. These insights have led to the development of various revolutionary macromolecular architectures, mimicking the structural features of proteins. In this review, we focus on the folding of single polymer chains into well-defined nanoparticles using supramolecular interactions and their possible use as enzyme mimics.

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Section: Folding Polymers Via Hydrogen-bond-driven Dimerizationmentioning

confidence: 99%

Supramolecular Single-Chain Polymeric Nanoparticles

Huurne¹,

Palmans

2019

CCS Chem

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“…The combination of hydrophobic interactions, metal complexation and electrostatic charges allowed Zimmerman and co-workers to develop a variety of dynamic SCNPs showing enzyme-like catalytic behavior ( Figure 5) [62,63] and, even, able to perform tandem reactions together with enzymes inside living cells [64]. Independently, the presence of compartmentalized ultra-fine nanoclusters in metal folded SCNPs and subdomains in their assemblies was reported by Cai et al [65], which used single chain technology to demonstrate unidirectional cross-domain molecule shutting of dumbbell-shaped SCNPs prepared by stepwise complexation of the outer blocks of an ABC-type linear triblock copolymer to copper ions [66].…”

Section: Multi-folded Single-chain Nanoparticles Via Non-covalent Bondsmentioning

confidence: 78%

Advances in the Multi-Orthogonal Folding of Single Polymer Chains into Single-Chain Nanoparticles

et al. 2021

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The folding of certain proteins (e.g., enzymes) into perfectly defined 3D conformations via multi-orthogonal interactions is critical to their function. Concerning synthetic polymers chains, the “folding” of individual polymer chains at high dilution via intra-chain interactions leads to so-called single-chain nanoparticles (SCNPs). This review article describes the advances carried out in recent years in the folding of single polymer chains into discrete SCNPs via multi-orthogonal interactions using different reactive chemical species where intra-chain bonding only occurs between groups of the same species. First, we summarize results from computer simulations of multi-orthogonally folded SCNPs. Next, we comprehensively review multi-orthogonally folded SCNPs synthesized via either non-covalent bonds or covalent interactions. Finally, we conclude by summarizing recent research about multi-orthogonally folded SCNPs prepared through both reversible (dynamic) and permanent bonds.

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“…HisMA monomer was obtained via the reaction of histamine with methacryloyl chloride. , 1 H NMR and 13 C NMR spectra suggest high purity (Figure S1). The diblock copolymer macro-CTA was synthesized via visible light-initiated RAFT aqueous solution polymerization. , 1 H NMR and SEC studies indicated well-defined CTA-1 (A 39 B 41 -TTC, Figure S2) and CTA-2 (B 43 A 38 -TTC, Figure S3) with the high fidelities of RAFT end groups.…”

Section: Resultsmentioning

confidence: 99%

Electrostatic Manipulation of Triblock Terpolymer Nanofilm Compartmentalization during Aqueous Photoinitiated Polymerization-Induced Self-Assembly

et al. 2020

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Electrostatic manipulation of triblock terpolymer nanofilm compartmentalization has been achieved via visible light-initiated reversible addition–fragmentation chain transfer aqueous dispersion polymerization of diacetone acrylamide monomer using cationic–neutral diblock copolymer macro-chain transfer agent (macro-CTA) at 25 °C. This photoinitiated polymerization-induced self-assembly (photo-PISA) evolves into two modes depending on solution pH. At pH 2.5, this macro-CTA dissolves in water with a fully cationic block; electrostatic repulsion leads to conventional aqueous photo-PISA and the formation of monolayer colloidal nanofilms. At pH 7.3, the cationic block transforms to a hydrophobic ionomer block with 10% cationic repeat units, and the copolymer chains self-assemble into weakly cationic micelles, which leads to seeded photo-PISA via self-assembly into discrete nanoclusters within the hydrophobic lamellar framework to form multicompartmentalized monolayer nanofilms. The nanoscale phase-separated 2D-confined nanoclusters and the lamellar structure can be tuned by the ABC/BAC block sequence, the degree of polymerization of the growing block, and the copolymer concentration. This electrostatic manipulation sheds new light on the rational design and preparation of multicompartmentalized block copolymer 2D nanoobjects.

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Metal‐Folded Single‐Chain Nanoparticle: Nanoclusters and Self‐Assembled Reduction‐Responsive Sub‐5‐nm Discrete Subdomains

Cited by 7 publications

References 43 publications

Supramolecular Single-Chain Polymeric Nanoparticles

Supramolecular Single-Chain Polymeric Nanoparticles

Advances in the Multi-Orthogonal Folding of Single Polymer Chains into Single-Chain Nanoparticles

Electrostatic Manipulation of Triblock Terpolymer Nanofilm Compartmentalization during Aqueous Photoinitiated Polymerization-Induced Self-Assembly

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